Applying Density Management to Develop Late Successional Features Klaus J. Puettmann Oregon State University.

Slides:

Advertisements

Similar presentations

CENTRAL CASCADES ADAPTIVE MANAGEMENT PARTNERSHIP An intersection of state and federal organizations, sharing and focusing science and management resources.

Advertisements

If You Build It Will They Come? Associations Between Birds and Vegetation Structure During Ten Years After Thinning Sveta Yegorova, Drs. Matt Betts, Joan.

Young Stand Thinning & Diversity Study: Songbird Response Joan Hagar USGS – Forest & Rangeland Ecosystem Science Center.

Riparian Thinning Logic

Flying Squirrel Response to Thinning in the Oregon Cascades Tom Manning 1, Joan Hagar 2, Brenda McComb 1 1 OSU - Forest Ecosystems and Society 2 USGS –

Habitat Use and Ecology of the Northern Flying Squirrel Todd M. Wilson USFS, PNW Research Station.

Key Features of Early Seral Habitats for Wildlife

Can we emulate early seral forest through silviculture? Klaus J. Puettmann Edmund Hayes Professor in Siviculture Alternatives Adrian Ares Research Associate.

Sustainable Landowner Options for Aspen Forests Charly Ray, Northern Ecosystem Services Jason Fischbach, UW-Extension June 8, 2013.

Uneven-aged beech stand, Germany. Uneven-aged mixed-hardwood stand, Michigan.

An Envirothon Primer Glenn “Dode” Gladders

Overstory and understory vegetation management to meet fire resilience and wildlife habitat objectives Eric Knapp, Becky Estes, and Carl Skinner U.S. Forest.

Silvicultural experiments exploring linkages between stand structural diversity and ecological variables in California Carl Skinner, Martin Ritchie, Eric.

“The conservation objective in the Mississippi Alluvial Valley is to provide forested habitat capable of supporting sustainable populations of all forest.

Key Recommendations and Products From a Series of Dry-Forest Workshops in Oregon and Washington Redmond, OR October 14, 2009.

NASP IMDS Stand Density THE BIG THREE: Absolute stand density Quadratic Mean Diameter Basal Area.

Stand Structure and Ecological Restoration Charles W. Denton Ecological Restoration Institute John D. Bailey, Associate Professor of Forestry, Associate.

Examining Clumpiness in FPS David K. Walters Roseburg Forest Products.

Climatic and biophysical controls on conifer species distributions in mountains of Washington State, USA D. McKenzie, D. W. Peterson, D.L. Peterson USDA.

Brief History of Site Quality Estimation from a Forest Mensuration Perspective Eric C. Turnblom ESRM Forest Soils and Site Productivity - Autumn.

Fall River Long-term Productivity Study : Predictions of Pre-harvest Biomass and Nutrient Pools K. Petersen, B. Strahm, C. Licata, B. Flaming, E. Sucre,

What Do You See? Message of the Day: The management objective determines whether a site is over, under, or fully stocked.

CLASS UPDATES Office hours: Fridays 9AM-12noon (or me for an appointment) Powerpoints – on class website Schedule changes: thesis statement, outline,

 Discuss silvicultural principles related to restoration/fuels treatments  Compare conditions from the 1900 Cheesman Lake reconstruction to current.

 Used by NRCS foresters  Simple and Quick way to determine  Average tree diameter  Range of tree diameters  Trees per acre  Stand composition 

What The Northwest Forest Plan says about 80+ year old trees.

What Do You See? Message of the Day: Use variable area plots to measure tree volume.

Hardwood Management in the Coast Region Implementation: A guide to where, when and how. Prepared by the Coast Region FRPA Implementation Team (CRIT) Silviculture.

Powered By Powered by: Simulating Regeneration Dynamics in Upland Oak Stands USDA Forest Service Southern Research Station Dr. David Loftis.

Opportunities for Restoring Second Growth Ecosystems in Staney Creek: Scientific Principles.

Tended intimate mixtures (tending stands or individual spruce) Advantages –Nursing effects are evenly distributed (better protection from radiation frost.

Hardwood Management in the Coast Region Implementation: A guide to where, when and how. Neil Hughes RPF Spring 2012.

The Potential of the Alder Resource: Challenges and Opportunities David Hibbs and Andrew Bluhm Hardwood Silviculture Cooperative Department of Forest Science.

An Ecologist’s Perspective on Valuing Nature Thomas A. Spies PNW Research Station.

Five Rivers Silviculture Workshop, April 23, 2003 Purposes of the workshop: Further refine the prescription for the pulsed pathway; Identify uncertainties.

John L. Willis, Forestry, Michigan State University, East Lansing, Michigan Michael B. Walters, Forestry, Michigan State University, East Lansing, Michigan.

Development and Implementation of a Red Alder Tree Farm Program Western Hardwood Association Annual Meeting June, 2005.

Evaluation of sampling alternatives to quantify stand structure in riparian areas of Western Oregon forests Theresa Marquardt Oregon State University Paul.

Effect of retained trees on growth and structure of young Scots pine stands Juha Ruuska, Sauli Valkonen and Jouni Siipilehto Finnish Forest Research Institute,

Do stem form differences mask responses to silvicultural treatment? Doug Maguire Department of Forest Science Oregon State University.

Alder Supply + Red Alder Plantation Growth and Yield RAP ORGANON Glenn Ahrens Oregon State University Extension Forester.

Extension of the forest ecosystem simulation model FORECAST: incorporating mountain pine beetle, fire, climate change, and wildlife Hamish Kimmins, Kim.

Stand initiation: South facing hillside, kept open by moisture limitations + repeated fires, Douglas-fir slowly invading (Kalamopsis.

Growth and Yield Lecture 6 (04/17/2015). Overview   Review of stand characteristics that affect growth   Basic Stand Growth Terminology Yield curve;

Thinning mixed-species stands of Douglas-fir and western hemlock in the presence of Swiss needle cast Junhui Zhao, Douglas A. Maguire, Douglas B. Mainwaring,

Effects of Intensive Fertilization on the Growth of Interior Spruce Presentation to: Interior Fertilization Working Group February 5/13 (revised March.

Concepts of Forest Regeneration

 Tier 1: Monitoring that will be done regardless of funding received:  Forest Service Preference is to focus on vegetation, e.g. Stand Structure including.

Over 80 years Late-successional Old-growth Raymond Davis Monitoring Lead Older Forests and Spotted Owls (Northwest Forest Plan Area) Defining Older Forests.

Forest Ecological Relationships: Teakettle and Plumas Lassen Administrative Study Malcolm North, Sierra Nevada Research Center, Davis, CA

Vegetation Module Seth Bigelow, Michael Papaik, Malcolm North USFS Pacific Southwest Research Station.

Looking for the Plateau in Douglas-fir Annual Volume Increment

RAP-ORGANON A Red Alder Plantation Growth Model David Hibbs, David Hann, Andrew Bluhm, Oregon State University.

Experimental gaps and biodiversity responses in the Vermont Forest Ecosystem Management Demonstration Project Bill Keeton Graduate student contributors:

Stand Development. Site Capability The ability of a forest to grow is related directly to physical site factors. Favourable physical factors create better.

Citation: Kato, A.., L. M. Moskal., P. Schiess, M. Swanson, D. Calhoun and W. Stuetzel, LiDAR based tree crown surface reconstruction. Factsheet.

Gary W. Miller USDA Forest Service Northern Research Station Morgantown, West Virginia Intermediate Stand Management – The Crop Tree Approach.

Silvicultural Systems for Mixedwood Management Phil Comeau Dept. of Renewable Resources University of Alberta.

Effect of wind disturbance on forest structure and composition Mariko Toda.

June 2016What problems/opportunities/needs are there with forest management? Development of the purpose of and need for action. July 2016What tools are.

Disturbance -Based Management Landscape-Level – Pattern and complexity – Stand age class distributions – Patch distributions: type, size, – shape, and.

Presentation Outline What is an irregular shelterwood system?

Concepts of Forest Regeneration

Cruise Summaries.

Establish a stratified mixture Underplanting

Twenty Years of Forest Development Following Restoration Thinning in Second Growth Douglas-fir Stands Paul Anderson, Program Manager USFS PNW Research.

Neighborhood Effects, Disturbance Severity, and Succession

Finding efficient management policies for forest plantations through simulation Models and Simulation Project

Management Of Dry-belt Douglas-fir

Kirk Hanson (360)

Presentation transcript:

Applying Density Management to Develop Late Successional Features Klaus J. Puettmann Oregon State University

Studies StudyLocation Overstory Species Age at thinning% max SDIRemarks ODF OR Coast RangeD-fir5-20NA Standard plantations Newton ColeCorvallisD-fir5020 – 40 Thinned previously Blodgett W. Hemlock5020 – 35 YSTDSWillamette NFD-fir4020 – 60 WildcatSuislaw NFD-fir3010 – 55 DMSBLMD-fir LindhWillamette NFD-fir PCT

Late successional features:  Overstory cover  Canopy layers  Large, dominant trees  Tree species mixtures, including hardwoods  Amount and composition of understory vegetation  Conifer regeneration  Spatial variability

Late successional features:  Overstory cover  Canopy layers  Large, dominant trees  Tree species mixtures, including hardwoods  Amount and composition of understory vegetation  Conifer regeneration  Spatial variability

Overstory Cover Willamette National Forest: Douglas-firBeggs 2005

Overstory cover Newton and Cole 2004 McDonald Forest: Douglas-fir, previously thinned

Crown structures Suislaw National Forest: Douglas-fir Chan et al. 2005

Foliage Height Diversity Index 0 m 10 m 5 m 30 m 25 m 20 m 15 m 35 m << STAND 1STAND 3STAND 2

Foliage Height Diversity Index 3 to 5 years after thinning Beggs 2005

Impact of thinning on volume and on growth rate (i.e., slope of volume curve)

Acceleration of “dominant old-growth” trees: Diameter growth of largest 6 tpa Growth (cm / yr) Willamette National Forest Beggs 2005

Douglas-fir Golden chinquapin Hardwoods Control 14.0 (a)27.1 (a)36.1 (a) (12.3 – 15.8)(19.4 – 34.9)(28.4 – 43.8) Heavy 4.7 (b)7.8 (b)18.0 (b) (0.1 – 9.3)(-1.1 – 16.7)(8.9 – 27.0) Light 5.9 (b)15.1 (a) (b)15.3 (b) (3.1 – 8.8)(1.5 – 28.8)9.0 – 21.6 LtGaps 4.0 (b)4.4 (b)13.4 (b) (0.8 – 7.2)(-3.6 – 12.5)(7.0 – 19.7) Overstory Mortality (%) Mostly competition related Beggs 2005

Late successional features:  Overstory cover  Canopy layers  Large, dominant trees  Tree species mixtures, including hardwoods  Amount and composition of understory vegetation  Conifer regeneration  Spatial variability

Late successional features:  Overstory cover  Canopy layers  Large, dominant trees  Tree species mixtures, including hardwoods  Amount and composition of understory vegetation  Tree regeneration  Spatial variability

Seedling survival 8 growing seasons after thinning Adapted from Maas-Hebner et al FEM

Seedling survival after 8 growing seasons Adapted from Maas-Hebner et al FEM

Seedling survival Newton and Cole 2004 McDonald: Douglas-fir

Western Red Cedar Douglas-firGrand FirWestern Hemlock Total % Damaged Harvesting damage to regeneration McDonald Forest Newton and Cole 2004

Impact of light availability on seedling growth Maas-Hebner et al. 2005

Western Hemlock Newton and Cole 2004 Impact of overstory density

Effects of weed control Western hemlock Newton and Cole 2004 Blodgett

Variation in overstory cover when gaps in interspersed in thinned stands Frequency Overstory Cover (%) Beggs 2005

Conclusions  Different late-successional components require different management strategies  Tradeoffs in terms of stand growth  Overstory and understory conditions before thinning are good indicators of responses  Some flexibility in thinning intensities  Repeated entries likely required

Density management needs to be an integral part of managing for late successional habitat, but additional measures, (gaps, snag creation, or remnant trees) are also necessary

Questions